• No results found

Allosteric Activation of the Par-6 PDZ Via a Partial Unfolding Transition

N/A
N/A
Protected

Academic year: 2021

Share "Allosteric Activation of the Par-6 PDZ Via a Partial Unfolding Transition"

Copied!
22
0
0

Loading.... (view fulltext now)

Full text

(1)

e-Publications@Marquette

Chemistry Faculty Research and Publications

Chemistry, Department of

6-26-2013

Allosteric Activation of the Par-6 PDZ Via a Partial

Unfolding Transition

Dustin S. Whitney

Medical College of Wisconsin

Francis C. Peterson

Medical College of Wisconsin

Evgeni L. Kovrigin

Marquette University, [email protected]

Brian F. Volkman

Medical College of Wisconsin

Accepted version.

Journal of the American Chemical Society,

Vol. 135, No. 25 ( June 26, 2013):

9377-9383.

DOI

. © 2013 American Chemical Society. Used with permission.

(2)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

1

Allosteric Activation of the Par-6

PDZ via a Partial Unfolding

Transition

Dustin S. Witney

Department of Biochemistry, Medical College of Wisconsin,

Milwaukee, WI

Francis C. Peterson

Department of Biochemistry, Medical College of Wisconsin,

Milwaukee, WI

Evgenii L. Kovrigin

Chemistry Department, Marquette University,

Milwaukee, WI

Brian F. Volkman

Department of Biochemistry, Medical College of Wisconsin,

Milwaukee, WI

(3)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

2

Abstract

Proteins exist in a delicate balance between the native and unfolded states, where thermodynamic stability may be sacrificed to attain the flexibility required for efficient catalysis, binding, or allosteric control. Partition-defective 6 (Par-6) regulates the Par polarity complex by transmitting a GTPase signal through the Cdc42/Rac interaction binding PSD-95/Dlg/ZO-1 (CRIB-PDZ) module that alters PDZ ligand binding. Allosteric activation of the PDZ is achieved by local rearrangement of the L164 and K165 side chains to stabilize the interdomain CRIB:PDZ interface and reposition a conserved element of the ligand binding pocket. However, microsecond to millisecond dynamics measurements revealed that L164/K165 exchange requires a larger rearrangement than expected. The margin of thermodynamic stability for the PDZ domain is modest (∼3 kcal/mol) and further reduced by transient

interactions with the disordered CRIB domain. Measurements of local

structural stability revealed that tertiary contacts within the PDZ are disrupted by a partial unfolding transition that enables interconversion of the L/K

switch. The unexpected participation of partial PDZ unfolding in the allosteric mechanism of Par-6 suggests that native-state unfolding may be essential for the function of other marginally stable proteins.

Introduction

Structural fluctuations in the native state of proteins are

essential for biological function.2 As originally defined by Anfinsen and

understood today, the native state is the most stable, kinetically accessible conformation.3 From a thermodynamic perspective, internal

picosecond to millisecond dynamics within most globular domains are viewed as small excursions around the global minimum of the

conformational energy landscape.4-7 However, a protein will populate

all thermodynamically (and kinetically) accessible states according to the relative free energy of each conformation. The population of unfolded protein in the native state is usually assumed to be negligible. This assumption may be perfectly valid when the

(4)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

3

equilibrium population of unfolded protein is small: A protein with ΔGfold = −5 kcal/mol is 99.97% folded. In contrast, when the free

energy of folding (ΔGfold) is marginal (e.g., −2 kcal/mol), a significant

fraction of the protein is unfolded (3.7%) at equilibrium at 25 °C. It follows that fluctuations in the native state of a marginally stable

protein may include frequent excursions to the unfolded state, partially folded states, or specific folding intermediates. Small domains with unfolding intermediates are less rare than once thought,8-10 and we

speculate that some proteins with a single, marginally stable fold might sample local minima in the conformational energy landscape to access structurally related but functionally distinct states.

The PSD-95/Dlg/ZO-1 (PDZ) domain of partition-defective 6 (Par-6) is a prototypical example of an allosteric PDZ for which the folding landscape is uncharacterized. Par-6 is a modular

scaffold/signaling protein that mediates cell polarity in several biological contexts.11-14 An adjacent Cdc42/Rac interaction binding

(CRIB) motif combines with the PDZ to form a module (CRIB-PDZ) that interacts with Cdc42, a small GTPase in the Rho subfamily. We recently demonstrated that the L164–K165 ‘dipeptide switch’ is the only apparent conformational change in the PDZ upon Cdc42 binding.11

Rearrangement of the side chains of L164 and K165 increases affinity for a C-terminal PDZ ligand 10-fold by inserting the K165 side chain into the peptide binding cleft. In the absence of Cdc42-GTP the L164 side chain points into the PDZ core toward the ligand-binding pocket and K165 is solvent exposed. In this low-affinity conformation (L164 ‘in’/K165 ‘out’) CRIB:PDZ interactions are weak and transient (Figure 1). To date, Par-6 is the only PDZ domain in which the carboxylate binding pocket is remodeled in order to regulate C-terminal ligand binding.

(5)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

4

Figure 1. L/K switch governs C-terminal ligand binding affinity in the Par-6 CRIB-PDZ

module. CRIB domain is colored red, PDZ domain is colored gray, and ligand binding cleft is colored red or green to signify low- or high-affinity state, respectively.

Our previous work suggested that the low- and high-affinity states of the CRIB-PDZ allosteric switch interconvert rapidly on the NMR chemical shift time scale.11 In the present study, we sought to

measure the intrinsic rate of the dipeptide switch by 15N relaxation

dispersion. Since switch interconversion scarcely alters PDZ structure we hypothesized that conformational exchange contributions (Rex)

would be localized to the immediate area of the switch itself. Instead, we found that dipeptide switching is linked to a domain-wide exchange event in the PDZ. The presence of unstructured CRIB residues

N-terminal to the PDZ destabilizes the native PDZ fold and increases access to an unfolding intermediate. Our results suggest that partial unfolding is required for allosteric regulation of the Par-6 CRIB-PDZ module.

Results

Peptide Binding Flips the L/K Switch in Par-6 CRIB-PDZ Our previous work suggested that the L/K switch flips when a C-terminal peptide (VKESLV) binds the Par-6 PDZ,11 but this

ligand-induced conformational change had not been directly detected. To monitor the conformational state of the dipeptide switch, we introduced a cysteine at position 164 within the L/K switch (CRIB-PDZL164C) and conjugated a nitroxide radical-containing spin label

(6)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

5

paramagnetic relaxation enhancement (PRE) effects from 1H–15N HSQC

peak intensities in the absence and presence of VKESLV. Backbone amides exhibiting MTSL-induced broadening in the apo state are shown in Figure 2A,B (Table S1). With the exception of two CRIB

residues, PREs fill and surround the PDZ binding pocket, indicating that the C164 side chain extends into the PDZ ligand binding cleft,

equivalent to the position of L164 in the low-affinity state. Peptide binding altered the PRE pattern substantially (Figure 2C,D, Table S1). Significant PREs throughout the CRIB domain and one face of the PDZ domain describe a new set of contacts with the spin label away from the peptide binding cleft. For example, peptide binding eliminated all the PREs in the β2 strand (G173, F174, Y175, I176) observed in the

apo state. Taken together, these data indicate that the C164-conjugated spin label evacuates the PDZ core to a solvent exposed position upon VKESLV binding, consistent with a ligand-induced rearrangement of the dipeptide switch from the low- to high-affinity PDZ conformation.11

Figure 2. VKESLV binding flips the L/K switch. PRE data for CRIB-PDZL164C. (A) Blue

spheres indicate broadened residues in the apo state. (B) iPRE (iPRE = 1 – Ipara/Idia) vs

residue number for CRIB-PDZL164C. Residues with significant iPRES values include:

A147 and I148 of the CRIB domain, S168 of the β1–2 loop; G174, F174, Y165, and

I176 of the β2 strand; and V239, N241, S242, and S243 of the α2 helix, and L245 and

I246 of the β6 strand. (C) Yellow spheres indicate broadened residues in

VKESLV-bound state (VKESLV:CRIB-PDZL164C ratio ≥ 6:1), where blue bars indicate those with

proximity to MTSL attached to C164 side chain. (D) iPRE vs residue number for CRIB-PDZL164C and VKESLV:CRIB-PDZL164C, where yellow bars indicate those with proximity

to MTSL attached to C164 side chain. Significant iPREs for the CRIB domain (S135, S137, I138, H140, D141, V145, A147, I149, D150), β1 strand (R160, V161), β1–2 loop

(S168, D169, K170, L172), β2–3 hairpin (L200), α1 helix region (E207, S208, T209,

G210, L211, V214), β4–5 region (I219, V221, N222, K229), α2 helix (N241, S242,

S243), and β6 strand (I246) highlight a surface of the PDZ domain distant from the

binding cleft (C,D). C164 is marked by a red sphere in (A,C). Proline residues are marked with a black asterisk, and residues without a calculated iPRE value are marked

(7)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

6

with a red “x”. A complete list of iPRE by residue for apo and VKESLV-bound states is located in Table S1.

Internal Motions of the PDZ Reveal Global Exchange

Throughout the Domain

We previously detected conformational exchange broadening in CRIB-PDZ near the L/K switch11,12 and speculated that the low- and

high-affinity states interconvert rapidly on the NMR chemical shift time scale. To define the intrinsic rate of L/K switch interconversion, 15N R2

dispersion was measured by (Carr–Purcell–Meiboom–Gill) (CPMG) experiments.15-17 Because L/K switch flipping appeared to be a minor

structural rearrangement, we expected limited R2 dispersions localized

to the switch region. Instead, significant R2 dispersions (Rex ≥ 1 s–1)

were detected at 32 sites in PDZ156–255 and 47 sites in CRIB-PDZ130–255

distributed across each protein (Figure 3A,B). Twenty-three

significantly exchanging residues were common to both constructs (Figure 3C), suggesting these domain-wide transitions might be reporting on the same exchange event.

Figure 3. 15N relaxation dispersion reveals a domain-wide transition in apo PDZ156–255

and CRIB-PDZ130–255. Representative dispersion curves for several sites of (A) PDZ156– 255 and (B) CRIB-PDZ130–255 as well as sites that lack dispersion and possess a flat,

featureless profile as a result. 1/τcp is the effective B1 frequency in the CPMG

experiment. (C) Pink spheres indicate residues with significant μs–ms exchange for both PDZ156–255 and CRIB-PDZ130–255. Red spheres indicate residues with significant

individual μs–ms exchange and those globally fitted for both PDZ156–255 and

(8)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

7

Residues that exhibit similar kex values in a folded domain are

likely to report on a single conformational exchange process.4 To

identify the dominant motional mode in each construct, 15N relaxation

dispersion data were subjected to a global fitting process.17-19 Global

fitting of 11 residues in PDZ156–255 and 16 residues for CRIB-PDZ130–255

yielded a rate (kex) of ∼1600 s–1 for each case (Table S2). Because

these internal motions are in the fast exchange regime, population ratios (pA, pB) and chemical shift differences (Δω) are not reliable for

direct comparison.17,19 However, similar kex values for PDZ156–255 and

CRIB-PDZ130–255 indicate that the CRIB does not measurably alter

intrinsic conformational exchange kinetics in the PDZ. CRIB-PDZ130–255

residues participating in concerted motion are found adjacent to the PDZ ligand-binding cleft (169, 174, 177, 232, and 243) near the CRIB:PDZ interface (161, 162, 243, and 247) and distributed

throughout the PDZ domain (179, 187, 213, 216, and 217 are all >10 Å from the ligand-binding cleft). PDZ156–255 residues participating in

similar motions are located in the PDZ ligand binding cleft (174, 177, and 235) and throughout the domain (179, 180, 188, 204, 207, and 220), but only one residue (162) is present at the CRIB:PDZ interface. Six residues (162, 174, 177, 179, 204, and 243) are common to the globally fitted populations of both constructs, and they cluster in or adjacent to the ligand-binding cleft of the PDZ, with four of those located in the β2–3 finger of the domain (Figure 3C). Detected motions

in PDZ156–255 and CRIB-PDZ130–255 are likely to be a similar exchange

event intrinsic to the PDZ and modified by the CRIB domain.

Par-6 PDZ Does Not Unfold by a Simple Two-State

Mechanism

Given the domain-wide nature of detected exchange in PDZ156– 255 and CRIB-PDZ130–255, we speculated that measured kex in the 1600

s–1 range may report on an unfolding transition.20,21 As a result, we

utilized single-jump stopped-flow kinetic folding measurements by monitoring fluorescence emission of Tyr 175 to determine folding and unfolding rates for PDZ156–255 and CRIB-PDZ130–255.22,23 In a simple

two-state protein folding mechanism, fluorescence-based kinetic folding curves can be fit to a single exponential, and both arms of the resultant chevron plot exhibit a linear dependence on denaturant concentration.24-26 The sum of folding (kf) and unfolding (ku) rate

(9)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

8

constants will be equal to the kex determined from 15N dispersion data

if they report on the same behavior. Both PDZ156–255 and CRIB-PDZ130– 255 kinetic stop-flow chevrons displayed nonlinearity (“chevron

rollover”) in the unfolding arm (Figure 4A), however. Importantly, estimations of folding rates assuming a simple two-state folding

mechanism yielded rate constants significantly below the measured kex

value (kf + ku = 65 s–1), indicating that global unfolding is far too slow

a process to account for detected exchange in the PDZ.

Figure 4. An intermediate is detectable in Par-6 unfolding. (A) Single-jump

stopped-flow chevron plots for CRIB-PDZ130–255 (black diamonds) and PDZ156–255 (gray circles).

Both chevrons display slight rollover in the unfolding arm. Nonlinearly fitted two-state folding equations are shown with black and gray lines for CRIB-PDZ130–255 and PDZ156– 255, respectively. (B) 1H–2D exchange vs [GnHCl] graph showing CRIB-PDZ130–255

residues. V234, T235, and M237 respond linearly to low [GnHCl], indicating their proximity to the region disrupted upon formation of the folding intermediate, and are colored red. All other residues are colored blue.

For Par-6 PDZ, chevron rollover in the unfolding arm is diagnostic of at least one unfolding intermediate in which the first transition state (TS1) has a higher energy barrier than the second (TS2), which is destabilized by addition of denaturant, causing an alteration in the rate-limiting step of protein unfolding.24,27,28 Earlier

reports indicate that PDZ domains do not fold by a two-state

mechanism, but instead sample at least one high-energy, on-pathway unfolding intermediate that is a feature of the PDZ domain family,5,28-30

(10)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

9

A Partial Unfolding Intermediate Is Detectable in

CRIB-PDZ

130–255

Unfolding intermediates are detectable in deuterium exchange experiments serially repeated at increasing levels of denaturant.31,32

Amide protons sensitive to partial unfolding excursions display linear dependence of ΔGHX on denaturant concentration, whereas unaffected

residues remain resistant to low denaturant levels and local effects govern their ΔGHX values.31,33 Divergent responses of

intermediate-sensitive and -inintermediate-sensitive residues persist until denaturant stabilizes the unfolded state, at which point ΔGHX values cluster at a similar

guanidine-driven global unfolding rate.8,30,34 We measured solvent

exchange in CRIB-PDZ130–255 at 0, 0.1, 0.2, 0.3, and 0.4 M guanidine

HCl at 10 °C. Multiple responses are visible in CRIB-PDZ130–255,

demonstrating the presence of at least one unfolding intermediate (Figure 4B, Table S4). Residues 234, 235, and 237 display a linear response to denaturant, whereas 221, 229, 233, 236, and 238 are insensitive to low levels of guanidine. These data are in agreement with the chevron rollover detected in kinetic folding measurements and confirm the presence of an unfolding intermediate in CRIB-PDZ130–255.

Flexible CRIB Destabilizes the PDZ Domain

Previously, we reported a small yet significant decrease of VKESLV binding affinity upon removal of the CRIB domain,11 and we

speculated that transient CRIB-mediated stabilization of the PDZ domain and ligand binding pocket was responsible.

We collected native 1H–2D exchange data for PDZ156–255 and

CRIB-PDZ130–255 to monitor the effect of CRIB residues on the PDZ

domain. Strikingly, protection factors were higher on average in PDZ156–255 than CRIB-PDZ130–255 (log PavePDZ = 1.78, log PaveCRIB-PDZ =

1.36), indicating a more rigid PDZ upon CRIB removal (Figure 5A,B). Free energies of unfolding (ΔGHX) may be calculated from fitted amide

solvent exchange constants,32,35 and the largest calculated ΔGHX value

from a protein reflects its global unfolding energy.30 ΔGHX values were

higher for PDZ156–255 (ΔG

HXPDZ = 3.4 ± 0.2 kcal/mol) than CRIB-PDZ130– 255 (ΔG

HXCRIB-PDZ = 2.9 ± 0.5 kcal/mol), suggesting that the CRIB

(11)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

10

Figure 5. Par-6 CRIB destabilizes the PDZ. Native 1H–2D exchange data by residue for

(A) CRIB-PDZ130–255 (black bars) and (B) PDZ156–255 (gray bars) at 25 °C. Dashed lines

connect residues that exhibit significant protection factors (log P) for both proteins. (C) Equilibrium guanidine denaturation measurements with increasing concentrations of GnHCl. Curves represent fitted functions used to determine ΔGGnHCl. Open circles

represent PDZ156–255 (ΔGunfPDZ = 3.2 ± 0.3 kcal/mol), and black diamonds signify

CRIB-PDZ130–255 (ΔGunfCRIB-PDZ = 2.8 ± 0.4 kcal/mol).

To confirm 1H–2D exchange results, we conducted

fluorescence-based (Tyr 175) equilibrium unfolding measurements which showed that CRIB-PDZ130–255 is significantly less stable than PDZ156–255

(ΔGunfCRIB-PDZ = 2.8 ± 0.4 kcal/mol, ΔGunfPDZ = 3.2 ± 0.3 kcal/mol,

Pcomparison = 0.013) (Figure 5C). A correlation plot comparing free

energies determined from both guanidine equilibrium unfolding and native deuterium exchange supports this conclusion as well (Figure S2C). The relatively modest ΔGunf values indicate that the Par-6 PDZ

domain is marginally stable in general and by comparison to other PDZ domains.24,27,30 Transient CRIB-PDZ interactions which promote

peptide binding (KD, VKESLVCRIB-PDZ = 54 ± 5 μM, KD,VKESLVPDZ = 72 ± 5 μM)

also destabilize the PDZ domain by ∼0.4 kcal/mol, demonstrating a PDZ destabilizing role for the free CRIB domain in Par-6.

(12)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

11

Par-6 Peptide Binding of the PDZ Domain “Quenches”

Exchange in Par-6 PDZ

In the absence of a peptide ligand, the PDZ domain has a

similar μs–ms exchange profile regardless of whether the flexible CRIB is present (Figure 3C). Peptide binding drives L/K switch conversion to the high-affinity position,11 so we measured R2 relaxation dispersions

in the presence of saturating amounts of ligand (VKESLV:protein > 6:1). Nine residues possess significant conformational exchange (Rex ≥

1 s–1) in VKESLV:PDZ156–255 compared to 32 in apo PDZ156–255 (Figure

6A). Five residues with significant dispersions in VKESLV:PDZ156–255

cluster near the CRIB:PDZ interface (157, 161, 212, 247, and 249), while no significant R2 dispersions were found in the ligand binding

pocket. No residues could be globally fitted in VKESLV:PDZ156–255 due

to dissimilar rate constants, marking a large reduction in domain-wide exchange relative to apo PDZ156–255. In contrast, the Rex dispersion

profile for VKESLV:CRIB-PDZ130–255 remained similar to CRIB-PDZ130–255

(Figure S1B). Global fitting of a subpopulation of residues sharing similar individual kex values yielded 15 sites fit to an exchange rate

(kex) of 1800 ± 200 s–1, similar to apo CRIB-PDZ130–255 (Table S3B).

Figure 6. VKESLV binding quenches Rex in PDZ156–255 and CRIB-PDZQ144C/L164C.

Comparison of CPMG-based R2 relaxation dispersion data for apo and VKESLV-bound

PDZ156–255 and CRIB-PDZQ144C/L164C. White spheres represent quenched dispersions for

VKESLV-bound Par-6 relative to apo state, red spheres those that retain dispersions, and yellow for dispersions detected only in VKESLV:PDZ156–255 are indicated in for (A)

VKESLV:PDZ156–255 and (B) VKESLV:CRIB-PDZQ144C/L164C. Nonexchanging residues are

colored blue. Representative dispersion curves demonstrating reduced Rex upon

VKESLV binding for both where black and white circles represent data for L200 in the apo and VKESLV-bound state, respectively. Black and white triangles represent data for V239 in the apo and VKESLV-bound state, respectively. VKESLV:protein ratio is 6:1. Analysis proceeded as described previously.1

(13)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

12

To determine if Rex quenching could be replicated by a stabilized

CRIB domain driving the high-affinity conformation of Par-6, we measured 15N R2 dispersion on a disulfide-stabilized CRIB-PDZ130–255

(CRIB-PDZQ144C/L164C, PDB entry: 2LC6), characterized previously.11

Only PDZ ligand binding pocket residues 174, 175, and 238 exhibited significant Rex in VKESLV:CPDZQ144C/L164C (Figure 6B), none of which are

near the CRIB:PDZ interface, diagnostic of a stable CRIB:PDZ interface. Notably, apo CRIB-PDZQ144C/L164C R

2 dispersion

measurements yielded a similar exchange profile to apo PDZ156–255 and

apo CRIB-PDZ130–255 (Figure S2D). In agreement with our findings,

equilibrium unfolding and deuterium exchange data indicate that CRIB-PDZQ144C/L164C is markedly more stable (ΔGunf = 5.1 ± 0.1 kcal/mol,

ΔGHX = 4.9 ± 0.1 kcal/mol) than CRIB-PDZ130–255 (Figure S2C).

Therefore, only interactions with a flexible CRIB domain promote instability in the PDZ domain even when peptide is bound in the PDZ ligand binding pocket.

Discussion and Conclusions

Allosteric activation of the Par-6 CRIB-PDZ module by Cdc42 is transmitted to the peptide binding site by a dipeptide switch that interconverts the side chains of L164 and K165 (Figure 1).11

Ligand-dependent changes in the pattern of paramagnetic broadening (Figure 2) demonstrated that peptide binding displaces L164 from the

carboxylate binding pocket, thereby switching to the high affinity L164 ‘out’/K165 ‘in’ configuration observed in Par-6 crystal structures and other PDZ domains. We measured 15N relaxation dispersion expecting

conformational exchange effects (Rex) near the L/K switch but instead

found that residues throughout the PDZ domain fluctuate at a common rate of ∼1600 s–1. The frequency of conformational exchange may be

correlated with dipeptide switch interconversion, but the effects extend well beyond the β1–2 loop, perhaps representing a domain-wide

process. The estimated rates of global folding and unfolding (Figure 4) were too slow (kex ∼ 65 s–1) to account for the observed Rex, but

additional measurements helped to identify a structural element within the PDZ domain that undergoes a concerted millisecond time scale rearrangement.

(14)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

13

R

2

Dispersions in Par-6 PDZ Report on Partial Unfolding

Native 1H–2D exchange data identified a set of residues

protected in both CRIB-PDZ130–255 and PDZ156–255 (K165, I195, L212,

E220, V221, I224, V226, V234, M237, M238, V239, and I246) (Figure 5) which delineate a stable ‘folding core’. This is important for two reasons: First, we observed widespread Rex throughout the PDZ

domain in all apo states of Par-6, (Figure 2), but careful inspection of the nonexchanging residues in each apo construct reveals a striking overlap with the stable PDZ core (Figure 7A). In contrast, exchanging residues are located in or adjacent to the β1–2 loop, which

encompasses the dipeptide switch, and the long β2–3 hairpin (Figure

3C). Second, two residues in the ‘folding core’ group (V234 and M237) display a linear dependence of ΔGHX at low guanidine concentrations, a

sign of nearby partial unfolding in the structure (Figure 7B).8,30 This is

consistent with previous reports utilizing ϕ-value analysis to determine

unfolding transition-state compositions of PDZ domains.28 They report

that the final folding barrier (TS2) involves docking of the β2–3 finger

into a folding core that includes the α2 helix. Taken together, our

measurements of Par-6 backbone dynamics and unfolding parameters are consistent with native-state access to an on-pathway unfolding intermediate similar to that observed for several other PDZ domains. Dissociation of the β2–3 finger from the rest of the PDZ core would give

the β1–2 loop additional flexibility and provides an opportunity for

(15)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

14

Figure 7. Segregation of dynamic and stable subdomains suggests a possible mode of

partial PDZ unfolding. (A) Pink spheres indicate residues with Rex ≥ 2 s–1 in

CRIB-PDZ130–255 and PDZ156–255 and red spheres indicate Rex ≥ 2 s–1 and those residues

globally fit for both. Light-blue and navy spheres indicate residues with detectable protection factors (the “folding core”), where the latter concurrently lack R2

dispersions. One residue, V239, is colored violet because it has a detectable protection factor and significant Rex. (B) Schematic of L/K switch isomerization via a partial

unfolding mechanism. Residue L164 is colored green, and K165 is colored purple. Brackets surrounding two center diagrams represent putative energetically equivalent states in the folding intermediate state. CRIB domain is colored red.

Cdc42-GTP Activation of the CRIB-PDZ

In the absence of Cdc42-GTP (or a high concentration of peptide ligand), the CRIB-PDZ module is predominantly in the low-affinity (L164 ‘in’ /K165 ‘out’) L/K switch configuration. Because Cdc42-GTP promotes isomerization of the L/K switch, which requires partial PDZ unfolding, we considered the possibility that the GTPase could also drive the unfolding process. However, NMR and crystallographic analysis showed that Cdc42 binds preferentially to the CRIB-PDZ module in the high-affinity (L164 ‘out’ /K165 ‘in’) conformation;11,12,36

formation of the CRIB:PDZ interface is incompatible with the low-affinity arrangement. Because Cdc42-GTP binding promotes folding of the CRIB and stabilizes the CRIB:PDZ interface, it seems unlikely that the GTPase catalyzes PDZ unfolding. Instead, we propose a model in which allosteric activation of the Par-6 L/K switch involves

spontaneous partial unfolding of the PDZ domain on microsecond– millisecond (μs–ms) time scales. In this model, Cdc42-GTP binding

(16)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

15

activates Par-6 by shifting a preexisting CRIB-PDZ conformational equilibrium toward the high-affinity configuration of the L/K switch.

Marginal Thermodynamic Stability As a Functional

Advantage

Evolutionary pressure tunes proteins for efficient function over all else, provided that sufficient folding energy is preserved.37 As a

consequence, thermodynamic stability of a protein structure will be compromised in order to gain functionality, as has been shown in T7 lysozyme.38 This reciprocal relationship between thermodynamic

stability and neofunctionalization was recently demonstrated for another member of the PDZ family. Smith et al. engineered a PKA substrate site into the ERBIN PDZ domain but found that efficient phosphorylation also required other destabilizing mutations.39 The

increase in flexibility, they concluded, was necessary to permit PKA to seize its target sequence for enzymatic activity.39 We observe a similar

reciprocal stability-function relationship in the Par-6 PDZ, where the modest margin of folding stability (ΔGunfold = 3.4 kcal/mol) ensures

frequent access to a partially unfolded state for dipeptide switch interconversion. Attachment of the CRIB domain further destabilizes the PDZ but increases its affinity for the VKESLV peptide. We conclude that, in the absence of Cdc42-GTP (or a high concentration of peptide ligand), transient interactions with the disordered CRIB enhance peptide ligand binding by selectively destabilizing the low-affinity PDZ conformation, thereby shifting the L/K switch equilibrium toward the high-affinity configuration.

Functional Unfolding in the Native State

Protein folding is an equilibrium process, and the unfolded state is significantly populated (>1%) in a protein of marginal stability (ΔGunfold < 2.8 kcal/mol) at 25 °C. We speculate that functional

advantages derived from protein destabilization often reflect a requirement for native-state access to an unfolded region of the

conformational energy landscape. Certain proteins undergo large-scale unfolding motions to undertake their biological roles. Lymphotactin, a prototypical ‘metamorphic’ protein, interconverts between a monomer with the canonical chemokine fold that activates its GPCR target and

(17)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

16

an unrelated all-β dimeric structure that binds extracellular matrix glycosaminoglycans.40-42 The need for an unfolding transition is

apparent when access to different functional states involves a

reversible global structural rearrangement. However, many proteins exchange between closely related conformations where native-state unfolding does not appear necessary. Our results suggest that partial unfolding of the Par-6 PDZ, perhaps populating an evolutionarily conserved23,29,30 intermediate, is required for allosteric activation of a

conformational switch that modulates ligand binding affinity. This is a direct demonstration of allosteric PDZ regulation by an unfolding transition, and we speculate that native-state unfolding contributes to the function of many other signaling proteins as well.

Materials and Methods

Mutagenesis, Protein Expression, and Purification

Drosophila melanogaster Par-6 proteins were produced as

previously described.12 CRIB-PDZQ144C/L164C variant purification

proceeded as previously described.11 Creation of the CRIB-PDZL164C

variant utilized QuikChange II Site-Directed Mutagenesis Kit

(Stratagene) and verified by DNA sequencing (Retrogen). All proteins were expressed and purified as previously described.11,12,43 Final

protein purity was measured as >99% by SDS-PAGE and MALDI-TOF spectroscopy.

NMR Spectroscopy

NMR experiments were carried out at 25 °C on a Bruker Avance 600 MHz or Bruker Avance III 500 MHz spectrometer equipped with a TCI CryoProbe. All NMR samples contained 0.75–1.25 mM 15N-labeled

protein and were prepared in 90% H2O/10% D2O containing 20 mM

NaHPO4, 20 mM NaAc pH 5.5, 50 mM NaCl, and 0.05% sodium azide.

NMR data were processed with the NMRPipe software package.44 The

Sparky program45 was used for peak intensity determination and

(18)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

17

Paramagnetic Relaxation Enhancement

PRE experiments proceeded as previously detailed,46 except that

purified 15N CRIB-PDZL164C protein was incubated overnight at 4 °C

with a 5-fold molar excess of MTSL (Toronto Research Chemicals) in a buffered solution containing 20 mM NaHPO4 pH 7.5, 20 mM NaAc, and 50 mM NaCl, and excess free thiol was removed by desalting column. Nitroxide radical quenching was accomplished by adding 5 μL of buffer-matched ascorbic acid solution to paramagnetic samples and incubating for 12 h at 25 °C to achieve full spin label quenching. 1H– 15N HSQC NMR spectra were measured before and after ascorbate

quenching to obtain peak intensity values for 15N CRIB-PDZ130–255.

Tabluation of peak intensities from paramagnetic and diamagnetic spectra allowed determination of paramagnetic relaxation caused directly by MTSL contact with the C164 side chain. iPRE values were calculated as

where DF represents the dilution factor upon addition of ascorbic acid. An iPRE value near 0 indicates a noncontacted residue, and a value near 1 indicates a backbone amide that makes close, consistent contact with the MTSL label and reports on full bleaching of the NMR signal in paramagnetic conditions.

R

2

Backbone Dispersion Experiments

Measurements of the transverse relaxation rate constant of 15N

amide nuclei proceeded as previously described.1 Relaxation rate

measurements were performed at 83 (6), 100 (6), 125 (6), 151 (6), 175 (5), 200 (6), 250 (6), 300 (6), 384 (5), and 555 (6) Hz (effective B1 field frequency). A reference experiment (zero relaxation delay) was

repeated 8 times for a total of 62 measurements per experiment. Data collection and analysis proceeded as previously described,19 except

that rcCPMG data sets were acquired at 15 and 25 °C at 11.7 and 14.1 T for all apo and VKESLV-bound proteins. VKESLV:protein ratio was ≥6:1 for all bound experiments to ensure full binding.

(19)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

18

Stopped-Flow Experiments for Determining Rates of

GnHCl-Induced Unfolding

Stopped-flow kinetic experiments were performed as previously detailed.42 All experiments used a final concentration of 25 μM protein

in solution. Curve fitting and data analysis proceeded as previously described,42 except that 5–10 traces per sample point were averaged

to determine kinetic rate constants. For folding measurements, a 1:1 dilution of buffered protein and GnHCl solution with a matched blank buffer was used. For unfolding measurements, 1:1 dilution of a buffered protein solution with a buffered GnHCl solution was used. Buffered solutions contained 25 mM NaHPO4 pH 5.5, 20 mM NaAc, and

50 mM NaCl. All unfolding experiments were conducted by rapid

mixing with GnHCl at multiple final concentrations (0.3, 0.35, 0.4, 0.5, 0.6, 1.0, 1.5, 2.0, 2.75, 3.0, 3.25, and 3.5 M).

Native

1

H–

2

D Exchange Experiments

Native deuterium exchange experiments were collected as serial

1H–15N HSQC spectra immediately following dilution of fully

protonated, lyophilized, and 15N-labeled proteins. Data analysis

proceeded as previously described.32,35 Experimental conditions for all

native exchange took place at pD 5.9, 25 °C. 1H–2D exchange vs

[denaturant] experiments were analyzed as previously detailed,8,30,31

except that all NMR experiments took place at pD 5.9, 10 °C. Guanidine HCl concentrations used were 0.1, 0.2, 0.3, and 0.4 M.

Equilibrium Unfolding Experiments and Determination

of Unfolding Free Energies

Measurements were performed as previously described,42 except

that the excitation wavelength of 274 nm was used with a bandwidth of 6 nm for tyrosine fluorescence. All proteins displayed a λmax at 304

± 2 nm. Buffered (20 mM Na2HPO4, 20 NaAc pH 5.5, 50 mM NaCl)

guanidine HCl stocks were used for all unfolding measurements.

Unfolding curves were recorded by monitoring fluorescence intensity at 304 nm as a function of guanidine concentration. Data analysis

(20)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

19

Supporting Information

iPRE values by residue, VKESLV:CRIB-PDZ130–255 R2 dispersion measurements, apo CRIB-PDZQ144C/L164C R2 dispersion measurements, CRIB-PDZQ144C/L164C unfolding analysis, global fitted population tables, and ΔGHX values at multiple guanidine concentrations. This material is available free of charge via the Internet at http://pubs.acs.org.

The authors declare no competing financial interest.

Acknowledgment

We would like to thank Dr. Blake Hill (Medical College of Wisconsin) for critical reading of this manuscript and Dr. Jim Feix (Medical College of Wisconsin) for assistance with spin labeling. This work was supported by NIH grant R01 AI058072.

References

1Buhrman, G.; O’Connor, C.; Zerbe, B.; Kearney, B. M.; Napoleon, R.; Kovrigina, E. A.; Vajda, S.; Kozakov, D.; Kovrigin, E. L.; Mattos, C. J.

Mol. Biol. 2011, 413, 773

2Villali, J.; Kern, D. Curr. Opin. Chem. Biol. 2010, 14, 636 3Anfinsen, C. B. Biochem. J. 1972, 128, 737

4Volkman, B. F.; Lipson, D.; Wemmer, D. E.; Kern, D. Science 2001, 291, 2429

5Zhang, J.; Sapienza, P. J.; Ke, H.; Chang, A.; Hengel, S. R.; Wang, H.; Phillips, G. N.; Lee, A. L. Biochemistry 2010, 49, 9280

6Mauldin, R. V.; Carroll, M. J.; Lee, A. L. Structure 2009, 17, 386 7Kern, D.; Zuiderweg, E. R. Curr. Opin. Chem. Biol. 2003, 13, 748 8Vu, N. D.; Feng, H.; Bai, Y. Biochemistry 2004, 43, 3346

9Went, H. M.; Benitez-Cardoza, C. G.; Jackson, S. E. FEBS Lett. 2004, 567, 333

10Serrano, A. L.; Bilsel, O.; Gai, F. J. Phys. Chem. B 2012, 116, 10631 11Whitney, D. S.; Peterson, F. C.; Volkman, B. F. Structure 2011, 19, 1711 12Peterson, F. C.; Penkert, R. R.; Volkman, B. F.; Prehoda, K. E. Mol. Cell

2004, 13, 665

13Horikoshi, Y.; Suzuki, A.; Yamanaka, T.; Sasaki, K.; Mizuno, K.; Sawada, H.; Yonemura, S.; Ohno, S. J. Cell Sci. 2009, 122, 1595

14Penkert, R. R.; DiVittorio, H. M.; Prehoda, K. E. Nat. Struct. Mol. Biol. 2004, 11, 1122

15Kempf, J. G.; Loria, J. P. Methods Mol. Biol. 2004, 278, 185 16Palmer, A. G., III Curr. Opin. Chem. Biol. 1997, 7, 732

(21)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

20

17Palmer, A. G., III; Kroenke, C. D.; Loria, J. P. Methods Enzymol. 2001, 339, 204

18Korzhnev, D. M.; Salvatella, X.; Vendruscolo, M.; Di Nardo, A. A.; Davidson, A. R.; Dobson, C. M.; Kay, L. E. Nature 2004, 430, 586

19O’Connor, C.; Kovrigin, E. L. Biochemistry 2008, 47, 10244

20Meinhold, D. W.; Wright, P. E. Proc. Natl. Acad. Sci. U.S.A. 2011, 108, 9078 21Tollinger, M.; Skrynnikov, N. R.; Mulder, F. A.; Forman-Kay, J. D.; Kay, L.

E. J. Am. Chem. Soc. 2001, 123, 11341

22Gianni, S.; Ivarsson, Y.; Jemth, P.; Brunori, M.; Travaglini-Allocatelli, C.

Biophys. Chem. 2007, 128, 105

23Gianni, S.; Calosci, N.; Aelen, J. M.; Vuister, G. W.; Brunori, M.; Travaglini-Allocatelli, C. Protein Eng., Des. Sel. 2005, 18, 389

24Chi, C. N.; Gianni, S.; Calosci, N.; Travaglini-Allocatelli, C.; Engstrom, K.; Jemth, P. FEBS Lett. 2007, 581, 1109

25Gianni, S.; Ivarsson, Y.; De Simone, A.; Travaglini-Allocatelli, C.; Brunori, M.; Vendruscolo, M. Nat. Struct. Mol. Biol. 2010, 17, 1431

26Calosci, N.; Chi, C. N.; Richter, B.; Camilloni, C.; Engstrom, A.; Eklund, L.; Travaglini-Allocatelli, C.; Gianni, S.; Vendruscolo, M.; Jemth, P. Proc.

Natl. Acad. Sci. U.S.A. 2008, 105, 19241

27Gianni, S.; Brunori, M.; Jemth, P.; Oliveberg, M.; Zhang, M. Biochemistry 2009, 48, 11825

28Gianni, S.; Geierhaas, C. D.; Calosci, N.; Jemth, P.; Vuister, G. W.;

Travaglini-Allocatelli, C.; Vendruscolo, M.; Brunori, M. Proc. Natl. Acad.

Sci. U.S.A. 2007, 104, 128

29Ivarsson, Y.; Travaglini-Allocatelli, C.; Jemth, P.; Malatesta, F.; Brunori, M.; Gianni, S. J. Biol.Chem. 2007, 282, 8568

30Feng, H.; Vu, N. D.; Bai, Y. J. Mol. Biol. 2005, 346, 345

31Chamberlain, A. K.; Handel, T. M.; Marqusee, S. Nat. Struct. Biol. 1996, 3, 782

32Bai, Y.; Milne, J. S.; Mayne, L.; Englander, S. W. Proteins 1993, 17, 75 33Raschke, T. M.; Marqusee, S. Curr. Opin. Biotechnol. 1998, 9, 80 34Bartlett, A. I.; Radford, S. E. Nat. Struct. Mol. Biol. 2009, 16, 582

35Nishimura, C.; Dyson, H. J.; Wright, P. E. Proc. Natl. Acad. Sci. U.S.A. 2005, 102, 4765

36Garrard, S. M.; Capaldo, C. T.; Gao, L.; Rosen, M. K.; Macara, I. G.; Tomchick, D. R. EMBO J. 2003, 22, 1125

37Pauling, L.; Pressman, D.; Campbell, D. H. Science 1943, 98, 263

38Shoichet, B. K.; Baase, W. A.; Kuroki, R.; Matthews, B. W. Proc. Natl. Acad.

Sci. U.S.A. 1995, 92, 452

39Smith, C. A.; Shi, C. A.; Chroust, M. K.; Bliska, T. E.; Kelly, M. J.; Jacobson, M. P.; Kortemme, T. Structure 2012, 21, 54

(22)

Journal of the American Chemical Society, Vol 135, No. 25 (June 26, 2013): pg. 9377-9383. DOI. This article is © American Chemical Society and permission has been granted for this version to appear in e-Publications@Marquette. American Chemical Society does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from American Chemical Society.

21

41Tuinstra, R. L.; Peterson, F. C.; Kutlesa, S.; Elgin, E. S.; Kron, M. A.; Volkman, B. F. Proc. Natl. Acad. Sci. U.S.A. 2008, 105, 5057 42Tyler, R. C.; Murray, N. J.; Peterson, F. C.; Volkman, B. F. Biochemistry

2011, 50, 7077

43Volkman, B. F.; Prehoda, K. E.; Scott, J. A.; Peterson, F. C.; Lim, W. A. Cell 2002, 111, 565

44Delaglio, F.; Grzesiek, S.; Vuister, G. W.; Zhu, G.; Pfeifer, J.; Bax, A. J.

Biomol. NMR 1995, 6, 277

45Goddard, T. D.; Kneller, D. G.SPARKY 3, University of California, San Francisco.

Chemistry Faculty Research and Publications Chemistry, Department of DOI n e-Publications@Marquette 1). e 2A, (Table S1). e 3A, e 4A) e 5A, 6A) : 2LC6), e 7A http://pubs.acs.org.

References

Related documents